Beta-Tricalcium Phosphate

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INNOTERE GmbH

Phone: +49 351 2599 9410

Fax: +49 351 2599 9429

Mail: order[at]innotere.de

Beta-tricalcium phosphate is a highly biocompatible, low-temperature polymorph of tricalcium phosphate (TCP). With its balanced resorption behavior, beta-TCP provides an ideal scaffold for bone regeneration, as it is gradually resorbed under physiological conditions and replaced by newly formed bone tissue. Using standardized production processes, INNOTERE offers beta-TCP powders with high phase purity and consistent batch-to-batch reproducibility.

Order Details

Name: Beta-tricalcium phosphate (β-TCP, tricalcium bis(orthophosphate), tribasic calcium phosphate)
Grade: Medical
CAS: 7758-87-4
Molecular Formula: Ca3(PO4)2
Molecular Weight: 310.18 g/mol
Phase Purity: >98%
Form: Powder
Applications: Bone cements, bone graft substitutes, coatings, 3D powder printing, drug delivery systems, dental fillers

Sieved or micronized powders with customized particle sizes, special packaging as well as particle size distribution charts, XRD data, specification sheets, MSDS, COA are available on request.

Featured Publications

Antibiotic-Loaded Polymer-Calcium Phosphate Scaffold for Treating Orthopedic Device-Related Infection in a Rabbit Segmental Bone Defect Model. Buchholz T, Siverino C, Moriarty TF, Sheehy EJ, O'Brien FJ, Nehrbass D, Arveladze S, Constant C, Elsayed SH, Yan M, Awad HA, Zeiter S, Allen MJ. Journal of biomedical materials research. Part A 2025
Poly(dl-lactide) Polymer Blended with Mineral Phases for Extrusion 3D Printing-Studies on Degradation and Biocompatibility. Vater C, Bräuer C, Grom S, Fecht T, Ahlfeld T, von Witzleben M, Placht AM, Schütz K, Schehl JM, Wolfram T, Reinauer F, Scharffenberg M, Wittenstein J, Hoess A, Heinemann S, Gelinsky M, Lauer G, Lode A. Polymers 2024
A comparative analysis of 3D printed scaffolds consisting of poly(lactic-co-glycolic) acid and different bioactive mineral fillers: aspects of degradation and cytocompatibility. Ahlfeld T, Lode A, Placht AM, Fecht T, Wolfram T, Grom S, Hoess A, Vater C, Bräuer C, Heinemann S, Lauer G, Reinauer F, Gelinsky M. Biomaterials Science 2023
Development of a new critical size defect model in the paranasal sinus and first approach for defect reconstruction - An in vivo maxillary bone defect study in sheep. Rothweiler R, Kuhn S, Stark T, Heinemann S, Hoess A, Fuessinger MA, Brandenburg LS, Roelz R, Metzger MC, Hubbe U. Journal of Materials Science: Materials in Medicine 2022
A fully ingrowing implant for cranial reconstruction: Results in critical size defects in sheep using 3D-printed titanium scaffold. Hubbe U, Beiser S, Kuhn S, Stark T, Hoess A, Schmitz HC, Vasilikos I, Metzger MC, Rothweiler R. Biomaterials Advances 2022